Rgb led touch panel and drive sense circuit

ABSTRACT

A drive-sense module for an RGB light emitting diode (LED) touch-sense panel includes light emitting diodes (LEDs) configured to emit light of different wavelengths and light blocking spacers configured to block light horizontal light detection between LEDs. The drive-sense module includes a plurality of LED touch sensors and a plurality of difference detection circuits, each LED touch sensor is coupled to one of the plurality of LEDs and configured to generate a signal representative of light detected by the LED in the first mode and a signal representative of light emitted by the LED in the second mode. A drive-sense circuit (DSC) is configured to forward bias the LED in the transmit mode and reverse bias the LED in the receive mode and a data output circuit is configured to generate a digital representation of light intensity of the current that is generated by the DSC.

CROSS-REFERENCE TO RELATED APPLICATIONS

The present U.S. Utility Patent Application claims priority pursuant to35 USC § 120 as a continuation of U.S. Utility application Ser. No.17/223,613, entitled “DRIVE SENSE CIRCUIT FOR AN LED TOUCH PANEL”, filedApr. 6, 2021, which is a continuation of U.S. Utility application Ser.No. 16/403,200, entitled “LIGHT EMITTING DIODE (LED) TOUCH DISPLAYCIRCUIT”, filed May 3, 2019, issued as U.S. Pat. No. 11,029,782 on Jun.8, 2021, both of which are hereby incorporated herein by reference intheir entirety and made part of the present U.S. Utility Application forall purposes.

STATEMENT REGARDING FEDERALLY SPONSORED RESEARCH OR DEVELOPMENT

Not Applicable.

INCORPORATION-BY-REFERENCE OF MATERIAL SUBMITTED ON A COMPACT DISC

Not Applicable.

BACKGROUND OF THE INVENTION Technical Field of the Invention

This invention relates generally to data communication systems and moreparticularly to sensed data collection and/or communication.

Description of Related Art

Sensors are used in a wide variety of applications ranging from in-homeautomation, to industrial systems, to health care, to transportation,and so on. For example, sensors are placed in bodies, automobiles,airplanes, boats, ships, trucks, motorcycles, cell phones, televisions,touch-screens, industrial plants, appliances, motors, checkout counters,etc. for the variety of applications.

In general, a sensor converts a physical quantity into an electrical oroptical signal. For example, a sensor converts a physical phenomenon,such as a biological condition, a chemical condition, an electriccondition, an electromagnetic condition, a temperature, a magneticcondition, mechanical motion (position, velocity, acceleration, force,pressure), an optical condition, and/or a radioactivity condition, intoan electrical signal.

A sensor includes a transducer, which functions to convert one form ofenergy (e.g., force) into another form of energy (e.g., electricalsignal). There are a variety of transducers to support the variousapplications of sensors. For example, a transducer is capacitor, apiezoelectric transducer, a piezoresistive transducer, a thermaltransducer, a thermal-couple, a photoconductive transducer such as aphotoresistor, a photodiode, and/or phototransistor.

A sensor circuit is coupled to a sensor to provide the sensor with powerand to receive the signal representing the physical phenomenon from thesensor. The sensor circuit includes at least three electricalconnections to the sensor: one for a power supply; another for a commonvoltage reference (e.g., ground); and a third for receiving the signalrepresenting the physical phenomenon. The signal representing thephysical phenomenon will vary from the power supply voltage to ground asthe physical phenomenon changes from one extreme to another (for therange of sensing the physical phenomenon).

The sensor circuits provide the received sensor signals to one or morecomputing devices for processing. A computing device is known tocommunicate data, process data, and/or store data. The computing devicemay be a cellular phone, a laptop, a tablet, a personal computer (PC), awork station, a video game device, a server, and/or a data center thatsupport millions of web searches, stock trades, or on-line purchasesevery hour.

The computing device processes the sensor signals for a variety ofapplications. For example, the computing device processes sensor signalsto determine temperatures of a variety of items in a refrigerated truckduring transit. As another example, the computing device processes thesensor signals to determine a touch on a touch screen. As yet anotherexample, the computing device processes the sensor signals to determinevarious data points in a production line of a product.

BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWING(S)

FIGS. 1A-1C are schematic block diagrams of examples of light emittingdiode (LED) biasing conditions;

FIG. 2 is an example of the current-voltage (I-V) characteristics oflight emitting diodes (LEDs) in a light emitting mode;

FIG. 3 is an example of the current-voltage (I-V) characteristics oflight emitting diodes (LEDs) in a light receiving mode;

FIG. 4 is a schematic block diagram of an embodiment of a light emittingdiode (LED) touch display cell in accordance with the present invention;

FIG. 4A is a schematic block diagram of another embodiment of a lightemitting diode (LED) touch display cell in accordance with the presentinvention;

FIGS. 5A-5B are schematic block diagrams of examples of generating aresponse output in accordance with the present invention;

FIGS. 6A-6B are examples of determining an interaction based on ambientlight level and distance of an object in accordance with the presentinvention;

FIG. 7 is a logic diagram of an example of a method of ambient lightbased touch detection by a light emitting diode (LED) touch display cellin accordance with the present invention;

FIGS. 8A-8B are schematic block diagrams of a light emitting diode (LED)touch sensor in accordance with the present invention;

FIGS. 9A-9D are schematic block diagrams of embodiments of a drive-sensecircuit in accordance with the present invention;

FIGS. 10A-10C are schematic block diagrams of a bi-directional dependentcurrent source in accordance with the present invention;

FIGS. 11A-11C are schematic block diagrams of embodiments of a datadrive input circuit in accordance with the present invention;

FIG. 12 is a schematic block diagram of an embodiment of a mode enablemodule and transmit/receive drive module in accordance with the presentinvention;

FIG. 13 is a schematic block diagram of an embodiment of a phase lockedloop (PLL);

FIG. 14 is a schematic block diagram of signals of the mode enablemodule and transmit/receive drive module in accordance with the presentinvention;

FIG. 15 is a schematic block diagram of another embodiment of the modeenable module and transmit/receive drive module in accordance with thepresent invention;

FIG. 16 is a schematic block diagram of signals of the mode enablemodule and transmit/receive drive module in accordance with the presentinvention;

FIG. 17 is a schematic block diagram of a light emitting diode (LED)touch display circuit in accordance with the present invention;

FIG. 18 is a schematic block diagram of an example of transmit andreceive select signals of light emitting diodes (LEDs) in accordancewith the present invention

FIGS. 19A-19B depict graphs of light versus object distance inaccordance with the present invention; and

FIG. 20 is a logic diagram of an example of a method of light basedtouch detection by a light emitting diode (LED) touch display circuit inaccordance with the present invention.

DETAILED DESCRIPTION OF THE INVENTION

FIGS. 1A-1C are schematic block diagrams of examples of light emittingdiode (LED) biasing conditions. An LED is a semiconductor diode thatconsists of p-type and n-type semiconducting materials placed in contactwith each other creating a p-n junction 12. N-type semiconductingmaterial is doped with donors that contribute free electrons whilep-type semiconducting material is doped with acceptors that createdeficiencies of electrons or positively charged holes.

FIG. 1A depicts an example of an LED in a zero bias condition 10. A zerobias condition is when no external potential energy is applied to thep-n junction 12. When the n-type and p-type materials (e.g., creatingp-region and n-region) are first joined, negatively charged freeelectrons 16 from the donor atoms migrate across the p-n junction 12 tofill positively charged holes 14 in the p-region leaving behindpositively charged donor ions 20. Holes 14 from the acceptor atoms inthe p-region migrate across the p-n junction 12 in the oppositedirection towards the free electrons leaving behind negatively chargedacceptor ions 18.

As a result, the charge density of the p-region along the p-n junction12 is filled with negatively charged acceptor ions 18 and the chargedensity of the n-region along the junction is filled with positivelycharged donor ions 20. This process repeats back and forth until thenumber of electrons which have crossed the junction have a large enoughelectrical charge to prevent any more electrons or holes from crossingover the junction. Eventually a state of equilibrium occurs producing anatural potential barrier zone around the p-n junction 12 where the p-njunction is depleted of free carriers (e.g., free electrons and holes).Thus, this area around the p-n junction 12 is referred to as thedepletion layer.

FIG. 1B depicts an example of an LED in a forward bias condition 22.When an LED is connected in a forward bias condition, a negative voltageis applied to the n-region and a positive voltage is applied to thep-region. If this external voltage becomes greater than the potentialbarrier (e.g., common values for threshold voltage lie between 0.6 and1.4 volts), the potential barrier's opposition will be overcome andcurrent will begin to flow as the negative voltage repels electronstowards the p-n junction 12 giving them energy to cross over and combinewith positively charged holes.

The application of the forward biased voltage 26 results in thedepletion layer becoming very small creating a low impedance paththrough the p-n junction 12 and allowing high currents to flow. Sincethe LED can conduct “infinite” current when forward biasing is above thevoltage threshold, the LED effectively becomes a short circuit in theforward bias condition and resistors are typically used in series tolimit its current flow.

In conventional diodes, when electrons combine with holes, energy in theform of heat it released. However, due to the semi-conductive materialschosen for LEDs, for each recombination of a negative and positivecharge, a quantum of electromagnetic energy is released in the form of aphoton 24 of light. The color of an LED depends on the combination ofsemiconductor materials used and the energy gaps (e.g., the amount ofenergy needed to move an electron from the valence band of an atom intoits conductance band) of the p and n regions.

The more energy the electrons lose in this process the higher thefrequency (and shorter the wavelength) of the light produced. DifferentLED compounds emit light in specific regions of the visible lightspectrum and therefore produce different intensity levels. The choice ofthe semiconductor material used determines the overall wavelength of thephoton light emissions and therefore the resulting color of the lightemitted. For example, to achieve a blue LED (e.g., a wavelength 430-505nm) silicon carbide (SiC) is used.

FIG. 1C depicts an example of an LED in a reverse bias condition 28.When an LED is connected in a reverse bias condition, a positive voltageis applied to the n-region and a negative voltage is applied to thep-region. The positive voltage applied to the n-region attractselectrons towards the positive electrode and away from the p-n junction.Likewise, the negative voltage applied to the p-region attracts holestowards the negative electrode and away from the p-n junction. Thedepletion layer grows wider due to a lack of electrons and holescreating a high impedance path. The LED in reverse bias acts like anopen circuit blocking the flow of current through the semiconductormaterial.

When an LED is operated in reverse bias mode, it can operate as aphotodiode. In other words, instead of emitting light, the LED candetect light. For example, when the p-n junction is illuminated withlight of a certain energy, incident photons 30 are absorbed andelectron-hole pairs 32 are created. Due to the reverse bias, theelectron-hole pairs drift apart. The movement of holes toward thenegative electrode (anode) and electrons toward the positive electrode(cathode) produces a photocurrent 36. This process is known as the innerphotoelectric effect.

LEDs detect a band of light that has a peak sensitivity at a wavelengthslightly shorter than the peak wavelength they emit. For example, an LEDwith a peak emission in red at 660 nm has a peak detection of about 610nm (e.g., orange light). LEDs used in near infrared remote controllersare AlGaAs devices with a peak emission of 880 nm and a peak detectionof 820 nm.

FIG. 2 is an example of the current-voltage (I-V) characteristics oflight emitting diodes (LEDs) in a light emitting mode. In a forward biascondition, once forward operating voltage (Vf) is reached, current is“infinite” in an LED and forward current are controlled by other circuitelements. Both the forward operating voltage (Vf) and forward currentvary depending on the semiconductor materials used. Most common LEDsrequire a forward operating voltage of between 1.2 to 3.6 volts with aforward current rating of about 10 to 30 mA with 12 to 20 mA being themost common range. As shown, with a forward current set at 20 mA, theforward voltage of a red LED is 1.8 volts, the forward voltage of theyellow LED is 2.2 volts, and the forward voltage of the green LED is 3.5volts.

The voltages and currents are typically less for mini-LEDs, micro-LEDs,and Organic LEDs (OLEDs) than they are for stand-alone LEDs. Whilecurrents and voltages are typically less, mini-LEDs, micro-LEDs, andOLEDs function in a similar manner to stand-alone LEDs as describedabove. As such, the concepts discussed herein are applicable tostand-alone LEDs, mini-LEDs, micro LEDs, and OLEDs. Note that amicro-LEDs generally refers to an LED that has a size less than 50microns and mini LEDs refer to LEDs that have a size that is greaterthan 50 microns.

FIG. 3 is an example of the current-voltage (I-V) characteristics oflight emitting diodes (LEDs) in a light receiving mode (e.g., operatingas a photodiode) where “p” is optical power (e.g., light intensity) andwhere p2 is greater than p1. As previously discussed, to be in a lightreceiving mode, the LED is reversed biased. This is also known asoperating in a photoconductive mode.

At zero optical power (e.g., p=0), the photocurrent (I) is almost zeroexcept for a small dark current. Dark current is produced due to randomgeneration of electrons and holes within the depletion layer of the LEDeven when no photons are entering the device. As shown, photocurrent isalmost independent of applied reverse bias voltage (Vr) while thephotocurrent varies almost linearly with incident lightintensity/optical power. For example, as reverse current increases,optical power (p) increases. As the reverse bias voltage increases,there is a sharp increase in the photocurrent. This point is referred toas breakdown voltage (Vbr).

FIG. 4 is a schematic block diagram of an embodiment of a light emittingdiode (LED) touch display cell 38 that includes LED 46, LED touch sensor50, processing module 52, and power supply 54. The LED touch displaycell 38 may further include a lens 48. The lens 48 includes one or morelight distribution properties, light concentration properties, filters,color masks, embedded text elements, and can also serve as a protectivelayer for LED 46. The LED touch display cell 38 may further include ashutter associated with the lens 48 to control light emissions and/orlight receptions.

The processing module 52 is a stand-alone device and/or part of acomputing device. A computing device is a portable computing deviceand/or a fixed computing device. A portable computing device includes asocial networking device, a gaming device, a cell phone, a smart phone,a digital assistant, a digital music player, a digital video player, alaptop computer, a handheld computer, a tablet, a video game controller,and/or any other portable device that includes a computing core. A fixedcomputing device is a computer (PC), a computer server, a cable set-topbox, a satellite receiver, a television set, a printer, a fax machine,home entertainment equipment, a video game console, and/or any type ofhome or office computing equipment that is relatively stationary.

The power supply 54 supplies may be implemented in a variety of ways toproduce a positive voltage Vdd, a negative voltage Vss, and a commonmode voltage Vcm (e.g., Vcm=0 volts). For example, the power supply 54is a DC-DC converter using a buck topology, a boost topology, abuck-boost topology, a fly-back topology, and/or a half-bridge topology.As another example, the power supply 54 includes one or more pairs of abatteries, where a pair of batteries is coupled in series with thecommon node providing Vcm.

The LED touch display cell 38 is operable to both emit light and senseambient light 42 and can be used in a variety of ways. For example, theLED touch display cell 38 is used as a button and/or switch (e.g.,on/off, dimmer) on any device such as a fan, an air filter, a computingdevice, etc. As another example, a plurality of LED touch display cellsis used in a touch screen display. As yet another example, an LED touchdisplay cell 38 is used as a near proximity motion detector.

In an example of operation, the LED touch sensor 50 generates a transmitsignal component of a transmit-receive (tx/rx) signal 55 based on adigital input (e.g., data_in) signal at a sample clock rate receivedfrom processing module 52. The LED touch sensor 50 further operates toproduce a digital data output (data_out) based on a receive signalcomponent of the transmit-receive signal 55. The transmit-receive signal55 is a repetitive signal that alternates between the transmit signalcomponents and the receive signal components. The transmit signalcomponent establishes a transmit mode and drives the LED 46 to a desiredlight intensity, which is based on the type of LED, the current beingsupplied, the voltage being supplied, the duration of being in thetransmit mode, and the duty cycle of the transmit-receive signal 55. Thereceive signal component establishes a receive mode and corresponds toan amount of light being received by the LED 46.

When the transmit signal component is active, the LED touch sensor 50forward biases the LED in accordance with a light intensity value (e.g.,a pulse width modulation (PWM) signal where the pulse width correspondsthe light intensity value) of the transmit signal component such thatthe LED 48 emits light and illuminates lens 48.

As an object 40 approaches the lens 48, the light emitted by the LED isreflected back. As more and more emitted light is reflected back, theproperties of the LED change. For instance, the forward bias voltage fora given current level changes (e.g., increases). The LED touch sensor 50generates a digital representation of the change in LED properties andoutputs it as data_out to the processing module 52.

When the receive signal component is active, the LED touch sensor 50reverse biases the LED such that the LED generates a current based onreceived light (e.g., ambient light 42). The LED touch sensor 50generates a digital representation of the current and outputs it asdata_out the processing module 52.

For example, when in a receive mode, the LED 46 senses ambient light 42around the LED touch display cell 38. Based on a varying distance 44 ofan object 40 (e.g., finger, pen, etc.) from the LED 46 and how thataffects the amount of ambient light 42 received by the LED 46, the LEDtouch display cell 38 interprets object 40 interactions (e.g., a touch,hover, hover and gesture, etc.) with the LED touch display cell 38. Forexample, if an object 40 is touching and fully covers the lens 48,ambient light 42 will be blocked out by the interaction.

The processing module 52 receives the data_out, which includes a digitalrepresentation of the current produced by the LED when it's receivinglight and includes a digital representation of changes in the LEDproperties when the LED is transmitting light. The processing moduleinterprets the digital representation of the current to produce adigital representation of the intensity of the ambient light. Theprocessing module 52 further processes the digital representation of theintensity of the ambient light to detect a touch, pressure of a touch, ahover, and/or a gesture. For example, the processing module determines atouch when a near-zero ambient light 42 is detected. As another example,the processing module determines a hover when the ambient light is lessthan a threshold level. As a further example, the processing moduleaugments the ambient light determination with the changing LEDproperties due to reflected light during the transmit mode. The level ofchange in the LED properties corresponds to level of light beingreflected. For instance, more light is reflected when the object isclose than when the object is further away.

FIG. 4A is a schematic block diagram of another embodiment of a lightemitting diode (LED) touch display cell 38 that includes the LED 46,another LED 51, the LED touch sensor 50, the processing module 52, thepower supply 54, and a lens 49. In this embodiment, the processingmodule 52, or the LED touch sensor 50, provides a signal to the anotherLED 51 such that LED 51 provides light to the lens 49, which functionsas a light waveguide for the light emitted by LED 51.

As an object 40 touches the lens 49, the touch causes some of the lightemitted by LED 51 to be reflected towards the LED 46. This is referredto as “frustrated total internal reflection”. During the receive mode,the LED 46 produces a current corresponding to the reflected light andthe LED touch sensor 50 generates a digital representation of thecurrent and outputs it as data_out. The processing module 52 processesthe data_out to determine the touch and may further determine thepressure of the touch based on the amount of light being received.

FIGS. 5A-5B are schematic block diagrams of examples of generating aresponse output. As mentioned above, during the receive signalcomponents, the LED touch sensor 50 receives a current from an LED 46.The LED touch sensor generates digital representations of the currentfrom the LED and the processing module 52 determines digitalrepresentations of light intensity 62 based on the digitalrepresentations of the current.

Over time, an ambient light pattern 58 is produced based on the digitalrepresentations of light intensity 62. The ambient light pattern 58includes a base ambient light 68 measurement with no blockages orchanges. The digital input signal to the LED touch sensor can beadjusted based on the base ambient light 68 measurement (e.g., whenthere is less ambient light, the LED emits less intense light).

The processing module interprets the ambient light pattern 58 todetermine an interaction (e.g., a touch, a touch pressure, a hover, agesture, etc.). For example, changes to the base ambient light 68 with aparticular rate of change 60 and/or that drop to a particular thresholdrepresent certain interactions. The processing module processes theinteraction to generate a response output.

In FIG. 5A, processing module establishes a base ambient lightmeasurement 68 based on the digital representations of light intensity62. The processing module interprets the ambient light pattern 58 todetermine changes from this base ambient light measurement 68. Forexample, the digital representations of light intensity 62 reduce at aparticular rate of change 60 to a point where there is little to noambient light detected.

The processing module interprets this ambient light pattern 58 as atouch interaction (e.g., as an object gets close to the LED, less andless ambient light is sensed). The processing module processes theinteraction to generate a response output 64. For example, the touch maycorrespond to a particular action (e.g., power on/off) and/or the lengthof the touch may correspond to a particular action (e.g., the length oftouch corresponds to a delta change in volume, light intensity of thelight emitted, window opening/closing, etc.).

In FIG. 5B, the processing module 52 establishes a base ambient light 68based on the digital representations of light intensity 62. Theprocessing module interprets the ambient light pattern 58 to determinechanges from this base ambient light measurement 68. For example, thedigital representations of light intensity 62 reduce at a particularrate of change 60 to a hover threshold level of light detected.

The processing module 52 interprets this ambient light pattern 58 as ahover interaction 66 (e.g., as an object hovers close to the LED, acertain level of ambient light is sensed). The processing moduleprocesses the interaction to generate a response output. For example, ahover interaction may be determined and then the processing module waitsfor further gesture information. A tap, swipe, length of hover, and/orother such gesture may be identified and processed to perform variousactions (e.g., power on/off, volume change, lighting change, etc.).Additionally, the processing module 52 can be adapted to discriminatebetween gesture and/or touch information (interaction) and changes toambient light and/or reflected light to LED 46 due to unrelated events,such as, for example, a display being placed in a user's pocket oragainst a user's face.

FIGS. 6A-6B are examples of determining an interaction based on ambientlight level and distance of an object. FIG. 6A depicts a graph ofambient light 42 versus varying distance 44 between an object and theLED touch display cell. A maximum (max) ambient light level 70 isestablished as the base ambient light measurement discussed previously.The max ambient light level 70 occurs when objects are further away fromthe LED touch display cell (e.g., at a greater distance 44) such thatambient light is not obstructed.

A hover threshold 72 is defined as being between a level of ambientlight associated with a distance d2 from the LED touch display cell andan ambient light level associated with a distance d1 from the LED touchdisplay cell. The level of ambient light associated with a distance d2is at a higher intensity than the ambient light level associated with adistance d1 and distance d2 is further from the LED touch cell surfacethan d1.

The processing module processes the digital representation of the lightintensity to determine an ambient light pattern and is able to determinea hover indication when the ambient light pattern deviates from themaximum ambient light level 70 to the hover threshold 72. The processingmodule can then process the hover indication to generate the responseoutput.

A touch threshold 74 is defined as being between a level of ambientlight associated with a distance d1 and zero ambient light at a distancezero. The processing module processes the digital representation of thelight intensity to determine an ambient light pattern and is able todetermine a touch indication when the ambient light pattern deviatesfrom the max ambient light 42 or the hover threshold 72 to the touchthreshold 74. The processing module can then process the touchindication to generate the response output.

FIG. 6B is a graph of rate of distance change 60 of an object and acorresponding perceived pressure 76. Rate of distance change 60 isdefined as the distance between two points (e.g., d2 and d1) divided bytime. Depending on how fast an object moves from a first point (d2) to asecond point (d1) within the hover threshold, the processing moduledetermines an interaction. For example, when an object moves veryquickly from d2 to d1, a higher pressure indicates an intended touch.When an object moves with slower speed from d2 to d1 a hover may beindicated as a lower pressure movement may not necessarily indicate atouch.

FIG. 7 is a logic diagram of an example of a method of ambient lightbased touch detection by a light emitting diode (LED) touch displaycell. The method begins with step 78 where a processing module of theLED touch display cell generates a data input signal (e.g., data_in) inaccordance with a sample clock rate. For example, the sample clock rateis 1/50 microseconds or 20 KHz which is a fast enough for the LED touchdisplay cell to switch from transmit and receive without detection bythe human eye.

The method continues with step 80 where an LED touch sensor of the LEDtouch display cell converts the data input signal into an LED signal(e.g., transmit-receive signal) where the LED signal includes a transmitsignal component and a receive signal component. The method continueswith step 82 where during the receive signal components, the LED touchsensor of the LED touch display cell receives a current from an LED ofthe LED touch display cell. The method continues with step 84 where theLED touch sensor generates digital representations of the current fromthe LED. The method continues with step 84 where the LED touch sensorgenerates digital representations of light intensity based on thedigital representations of the current.

The method continues with step 88 where the LED touch sensor sends thedigital representations of light intensity as a data output signal(e.g., data_out) to the processing module. The method continues withstep 90 where the processing module processes the digitalrepresentations to determine an ambient light pattern. The ambient lightpattern is determined by first establishing a base ambient lightmeasurement with no blockages or changes. The input data signal to theLED touch sensor can be adjusted based on the base ambient lightmeasurement (e.g., when there is less ambient light, the LED emits lessintense light when in transmit mode).

The method continues with step 92 where the processing module interpretsthe ambient light pattern to determine an interaction (e.g., a touch,hover, hover and gesture, etc.). For example, a hover threshold isdefined as being between a level of ambient light associated with asecond distance from the LED touch display cell and an ambient lightlevel associated with a first distance from the LED touch display cell.The level of ambient light associated with second distance is at ahigher intensity than the ambient light level associated with the firstdistance and the second distance is further from the LED touch cellsurface than the first distance.

The processing module processes the digital representation of the lightintensity to determine an ambient light pattern and is able to determinea hover interaction when the ambient light pattern deviates from thebase ambient light level to the hover threshold.

A touch threshold is defined as being between a level of ambient lightassociated with the first distance and zero ambient light at a distancezero. The processing module processes the digital representation of thelight intensity to determine an ambient light pattern and is able todetermine a touch indication when the ambient light pattern deviatesfrom the base ambient light or the hover threshold to the touchthreshold.

Further, rate of distance change and a corresponding perceived pressurecan be used to determine an interaction. Rate of distance change isdefined as the distance between two points (e.g., the second and firstdistance) divided by time. The faster an object moves from the seconddistance (d2) to the first distance (d1) (e.g., through the hoverthreshold region), the greater the perceived pressure. The processingmodule determines an interaction based on perceived pressure. Forexample, when an object moves very quickly from d2 to d1, a higherpressure indicates an intended touch. When an object moves with slowerspeed from d2 to d1 a hover may be indicated as a lower pressuremovement may not necessarily indicate a touch.

The method continues with step 94 where the processing module processesthe interaction to determine a response output. For example, a tap,swipe, length of touch/hover, and/or or other such gesture may beidentified and processed to perform various actions (e.g., power on/off,volume change, lighting change, etc.). A hover interaction may bedetermined and then the processing module waits for further gestureinformation.

FIGS. 8A-8B are schematic block diagrams of a light emitting diode (LED)touch sensor 50 that includes data drive input circuit 96, drive-sensecircuit 98, data output circuit 100, and LED 46. Data drive inputcircuit 96 is operable to generate a transmit-receive signal (e.g.,analog input signal 102 or LED signal) based on a digital input (e.g.,data_in). The transmit-receive signal includes a transmit signalcomponent and a receive signal component. For example, thetransmit-receive signal may be a sinusoidal or a square wave signal witha fixed period and a transmit duration based on light intensity. Forexample, the transmit signal component includes a pulse width modulation(PWM_(in)) signal component representative of a light intensity value.Data drive input circuit 96 is discussed in greater detail withreference to FIGS. 11A-16.

FIG. 8A depicts LED touch sensor 50 in a transmit mode and FIG. 8Bdepicts LED touch sensor 50 in a receive mode. In FIG. 8A, when thetransmit signal component is active, drive-sense circuit 98 forwardbiases the LED in accordance with a light intensity value (e.g.,PMW_(in)) of the transmit signal component of analog input signal 102such that the LED emits light in accordance with a transmit currenti_(tx). Drive-sense circuit 98 also outputs digital signal 104 to dataoutput circuit 100 for output processing. Drive-sense circuit 98 isdiscussed in greater detail with reference to FIGS. 9A-10C. When intransmit mode, digital signal 104 represents loop error corrections dueto changes in the transmit current i_(tx). Data output circuit 100outputs the error correction signal as data_out.

In FIG. 8B, when the receive signal component is active, drive-sensecircuit 98 reverse biases LED 46 such that the LED generates a currentbased on received light. Drive-sense circuit 98 generates a digitalrepresentation of the current (e.g., digital signal 104). Data outputcircuit 100 produces a digital representation of light intensity basedon digital signal 104 as output signal data_out.

FIGS. 9A-9D are schematic block diagrams of embodiments of drive-sensecircuit 98. Drive-sense circuit 98 includes resistive network 110,bi-directional dependent current source 106, operational amplifier(op-amp) 112, and analog to digital converter 108. Resistive network 110include a first resistive divider (e.g., R1 and R2) and a secondresistive divider (e.g., R3 and R4). Each resistive divider operates asa current-to-voltage conversion circuit. Resistive network 110 receivesanalog input signal 102 from data drive input circuit 96 and generatesinput voltages for op-amp 112. For example, the first resistive dividergenerates a reference signal voltage (e.g., v_in2) from analog inputsignal 102 and the second resistive divider generates a data signalvoltage (e.g., v_in1) from analog input signal 102.

Analog input signal 102 has a receive signal component and a transmitsignal component. For example, analog signal 102 is a sinusoidal wavewhere a positive amplitude corresponds to a transmit data component anda negative amplitude corresponds to a receive data component. The lengthof the transmit component determines the light intensity value. Asanother example, analog signal 102 is a square wave.

Op-amp 112 is a difference detection circuit that outputs an appropriateoutput voltage (error correction (EC) signal 114) such thatbi-directional dependent current source 106 can generate the errorcorrection current (iEC) needed to keep op-amp 112 inputs v_in1 andv_in2 equal. Alternatively, other types of difference detection circuitsmay be used such as a comparator circuit.

Bi-directional dependent current source 106 is operable to generate anerror correction current (iEC) based on the error correction signal 114in order to cause the data signal voltage (e.g., v_in1) to substantiallymatch reference signal voltage (e.g., v_in2).

Analog to digital converter 108 may be implemented as a flash analog todigital converter (ADC), a successive approximation ADC, a ramp-compareADC, a Wilkinson ADC, an integrating ADC, a delta encoded ADC, and/or asigma-delta ADC. Analog to digital converter 108 converts the analogerror correction signal output from op-amp 112 to digital signal 104.The analog to digital converter 108 sends the digital signal 104 to dataoutput circuit 100 for further output processing.

When the transmit signal component is active, the drive-sense circuit 98operates to forward bias the LED in accordance with a light intensityvalue. When the receive signal component is active, the drive-sensecircuit 98 operates to reverse bias the LED such that the LED generatesa current based on received light and generates a digital representationof the current.

FIG. 9A depicts drive-sense circuit 98 in a receive mode (e.g., thereceive component of analog input signal 102 is active). In receivemode, common mode voltage (Vcm) is equal to 0 volts and the receivecomponent of the analog input signal has an amplitude of Vss. Forexample, Vss is equal to −5 volts. The first resistive divider (e.g., R1and R2) of resistive network 110 generates a reference signal voltage(e.g., v_in2) based on the receive component of analog input signal 102.For example, the reference signal voltage is −2.5 volts when Vss is −5and R1=R2.

The second resistive divider (e.g., R3 and R4) of resistive network 110generates a data signal (e.g., v_in1) to reverse bias the LED. Inreceive mode, the LED generates a current (iRx) based on received light.Therefore, the data signal is based on the current produced by the LED(iRx), the receive component, and the error correction current (iEC)generated by the bi-directional dependent current source 106.

Op-amp 112 is powered by a positive voltage source (Vdd) and a negativevoltage source (Vss). The output voltage of the op-amp 112 is errorcorrection signal 114 which represents the voltage needed forbi-directional dependent current source 106 to generate the correcterror correction current iEC to keep v_in1 and v_in2 equal. V_in1 isequal to (iRx+iEC)×R3 and v_in2 is equal to iref×R2. Therefore, in orderfor v_in1 and v_in2 to be equal, iRx+iEC needs to equal iref. As iRxincreases due to light detection, iEC is decreased based on errorcorrection signal 114. The error correction signal 114 is representativeof the current change due to light detection. Op-amp 112 outputs errorcorrection signal 114 to the bi-directional dependent current source 106and analog to digital converter 108.

Bi-directional dependent current source 106 generates the value of iECrequired to keep v_in1 and v_in2 equal. Bi-directional dependent currentsource 106 will be discussed in greater detail with reference to FIGS.10A-10C. Analog to digital converter 108 converts the error correctionsignal 114 to digital signal 104 representative of the current of thereceived light. Analog to digital converter 108 sends digital signal 104to data output circuit 100 for further output processing (e.g., dataoutput circuit 100 produces a digital representation of light intensitybased on the digital representation of the current) to produce a dataoutput signal (data_out).

FIG. 9B depicts drive-sense circuit 98 in a transmit mode (e.g., thetransmit component of analog input signal 102 is active). In transmitmode, common mode voltage (Vcm) is equal to 0 volts and the transmitcomponent of the analog input signal has an amplitude of Vdd. Forexample, Vdd is equal to 5 volts. The first resistive divider (e.g., R1and R2) of resistive network 110 generates a reference signal voltage(e.g., v_in2) based on the transmit component of analog input signal102. For example, the reference signal voltage is 2.5 volts when Vdd is5 volts and R1=R2. Alternatively, a fraction of Vdd can be used fortransmit mode so that current during receive mode is greater as comparedto transmit mode. An accurate digital signal 104 measurement is moreimportant during receive mode (e.g., the measurement of received light)therefore the circuit can be biased to get a more accurate measurementduring the receive mode.

The second resistive divider (e.g., R3 and R4) of resistive network 110generates a data signal (e.g., v_in2) to forward bias the LED. Intransmit mode, the LED current (iTx) or drive current is fixed based onthe type of LED used. Op-amp 112 is powered by a positive voltage source(Vdd) and a negative voltage source (Vss). The output voltage of theop-amp 112 is error correction signal 114 and represents the voltageneeded for bi-directional dependent current source 106 to generate theerror correction current iEC in order to keep v_in1 and v_in2 equal.V_in1 is equal to (iTx+iEC)×R3 and v_in2 is equal to iref×R2. Therefore,in order for v_in1 and v_in2 to be equal, iTx+iEC needs to equal iref.

Op-amp 112 outputs error correction signal 114 to the bi-directionaldependent current source 106 and analog to digital converter 108.Bi-directional dependent current source 106 generates error correctioncurrent (iEC) to ensure the inputs to op-amp 112 are equal. Analog todigital converter 108 converts the analog error correction signal 114output from op-amp 112 to digital signal 104. Analog to digitalconverter 108 sends digital signal 104 to data output circuit 100 forfurther output processing to produce a data output signal (data_out).

The digital signal 104 contains information regarding light beingreflected back onto the LED 46. For example, when no object is near theLED 46 in transmit mode, no light from the LED is reflected back on it.As another example, as an object gets closer and closer to the LED 46,more and more light is reflected back on the LED. The reflected lightaffects the voltage-current curve of the LED in the forward biasdirection. The change in the voltage-current curve is represented in thedigital signal 104 and can be interpreted to augment a touch, hover,and/or gesture movement.

FIG. 9C operates similarly to FIGS. 9A and 9B, except drive-sensecircuit 98 includes a capacitance feedback circuit having one or morecapacitors and/or resistors. The circuit may further include a secondcapacitor coupled across the input of op-amp 112. In this example, thecapacitance feedback circuit includes capacitor (C1) coupled to thepositive input of op-amp 112 and to the output of op-amp 112. Optionalinput capacitor (C2) is coupled to both inputs of op-amp 112 forpotential further transient response.

The capacitance feedback circuit dampens transitions that occur when thedrive sense circuit switches between transmit and receive mode. Theoutput voltage (e.g., the error correction signal) is stored in thecharge of the feedback capacitor C1 to account for fast inputtransitions and propagation delay of op-amp 112. Optional inputcapacitor C2 improves high-frequency response (e.g., high frequencynoise with high impedance can be attenuated with a low-valued capacitor)but may introduce instability. However, the capacitance feedback circuit(C1) can compensate for input capacitance instability.

FIG. 9D operates similarly to FIG. 9C except drive-sense circuit 98further includes digital to analog converter (DAC) 116 connected to theoutput of analog to digital converter 108 and the input ofbi-directional dependent current source 106. The DAC 116 is one of asigma-delta DAC, a pulse width modulator DAC, a binary weighted DAC, asuccessive approximation DAC, and/or a thermometer-coded DAC.

Op-amp 112 outputs error correction signal 114 to analog to digitalconverter 108. Analog to digital converter 108 converts error correctionsignal 114 to a digital signal 104 where it is output to data outputcircuit 100 for further processing. Analog to digital converter 108 alsosends digital signal 104 to digital to analog converter 116 wheredigital to analog converter 116 converts digital signal 104 back to ananalog signal for input into bi-directional dependent current source106. With, Iref*R2=IR4*R4, the resistance R2 may be selected to be muchlarger than R4 such that most current is through the LED and not thefirst resistive divider of resistive network 110. Note that the DAC 166may be included on any one of the embodiments of the drive sense circuitdiscussed herein.

FIGS. 10A-10C are schematic block diagrams of bi-directional dependentcurrent source 106. Bi-directional dependent current source 106 takeserror correction (EC) signal 114 (Vin) and generates an error correctioncurrent (iEC) to compensate for current changes created by lightemitting diode (LED) (e.g., current generated due to light detection ina receive mode and fixed current used to drive the LED in a transmitmode).

As shown in FIG. 10A, bi-directional dependent current source 106includes operational amplifier (op-amp) 116 that is powered by apositive voltage source (Vdd) and a negative voltage source (Vss). Afirst impedance (e.g., resistor R5) is coupled to a positive input ofop-amp 116 and receives the error correction (EC) signal 114 or Vin.

A second impedance (e.g., resistor R7) is coupled to a reference voltage(Vcm=0) and to a negative input of op-amp 116. A third impedance (e.g.,resistor R6) coupled to the positive input of op-amp 116 and to anoutput of bi-directional dependent controlled current source 106. Afourth impedance (e.g., resistor R8) is coupled from the negative inputto the output of op-amp 116. A fifth impedance e.g., resistor R9)coupled from the output of op-amp 116 and to the output ofbi-directional dependent current source 106. Impedance values and op-amp116 operational characteristics are chosen such that the appropriatevalue of iEC is generated.

FIG. 10B depicts bi-directional dependent current source 106 in areceive mode (e.g., the receive component of analog input signal 102 isactive). In receive mode, common mode voltage (Vcm) is equal to 0 voltsand the receive component of the analog input signal has an amplitude ofVss. For example, Vss is equal to −5 volts. The first resistive divider(e.g., R1 and R2) of resistive network 110 of the drive-sense circuitgenerates a reference signal voltage (e.g., v_in2) based on the receivecomponent of analog input signal 102. For example, the reference signalvoltage is −2.5 volts when Vss is −5 and R1=R2.

The second resistive divider (e.g., R3 and R4) of resistive network 110generates a data signal (e.g., v_in1) to reverse bias the LED. Inreceive mode, the LED generates a current (iRx) based on received light.As a specific example, the light received by the LED generates a currentof 1 mA. Therefore, iRx=1 mA. In order for v_in1 to equal v_in2 (e.g.,−2.5 volts), bi-directional dependent current source 106 generates iECsuch that iEC+iRx is equal to iR4. In this example, iR4 is equal to 25mA (e.g., −2.5−(−5)=2.5 V/100 ohms=25 mA, where R4=100 ohms).

Error correction (EC) signal 114 is the voltage required forbi-directional dependent current source 106 to generates errorcorrection current iEC such the irX+iEC=iR4. For example, bi-directionaldependent current source 106 generates iEC to equal 24 mA (e.g., 1 mA+24mA=25 mA).

FIG. 10C depicts bi-directional dependent current source 106 in atransmit mode (e.g., the transmit component of analog input signal 102is active). In transmit mode, common mode voltage (Vcm) is equal to 0volts and the transmit component of the analog input signal has anamplitude of Vdd. For example, Vdd is equal to 5 volts. The firstresistive divider (e.g., R1 and R2) of resistive network 110 generates areference signal voltage (e.g., v_in2) based on the transmit componentof analog input signal 102. For example, the reference signal voltage is2.5 volts when Vdd is 5 volts and R1=R2.

The second resistive divider (e.g., R3 and R4) of resistive network 110generates a data signal (e.g., v_in1) to forward bias the LED. Errorcorrection (EC) signal 114 is the voltage required for bi-directionaldependent current source 106 to generate the appropriate errorcorrection current iEC. In transmit mode, the LED current (iTx) is fixedbased on the type of LED used. In order for v_in1 to equal v_in2 (e.g.,2.5 volts), bi-directional dependent current source 106 generates iECsuch that iEC+iTx is equal to iR4. For example, if iTx is equal to −20mA to drive the LED and iR4 is equal to −25 mA (e.g., 2.5−5V=−2.5V/100ohms=−25 mA, where R4=100 ohms), then bi-directional dependent currentsource 106 generates iEC to equal −5 mA (e.g., −5 mA−20 mA=−25 mA).

FIGS. 11A-11C are schematic block diagrams of embodiments of data driveinput circuit 96 that includes pulse width modulation (PWM) module 118,transmit/receive drive module 120, and mode enable module 122. Datadrive input circuit 96 takes an input signal (e.g., data_in) which isconventionally used for display and converts it to analog input signal102. Analog input signal 102 has two purposes: mode select and dataconveyance.

As shown in FIG. 11A, data_in is received by PWM module 118. PWM module118 generates PWM signal 128 based on data_in and in accordance withclock signal 124. PWM signal 128 represents both the data and modeselect. For example, the brighter the display data (e.g., data_in), thelonger the LED is in transmit mode. The pulse width of the PWM signalindicates the length of the transmit mode and thus a light intensityvalue. Further, with the PWM signal 128 high, the LED is in transmitmode and when the PWM signal 128 is low, the LED is in receive mode.

Mode enable module 122 receives PWM signal 128 and establishes an LEDtransmit mode of mode signal 126 when the PWM signal 128 is in a firststate (e.g., high) and establishes an LED receive mode of the modesignal 126 when the PWM signal 128 is in a second state (e.g., low).

PWM signal 128 and mode signal 126 are received by the transmit/receivedrive module 120. When the mode signal 126 received indicates thetransmit mode, transmit/receive drive module 120 generates a transmitdata signal component of analog input signal 102 based on the PWM signal128. When the mode signal 126 received indicates the receive mode,transmit/receive drive module 120 generates a receive signal componentof the analog input signal 102 based on the PWM signal 128.

Transmit/receive drive module 120 outputs the analog input signal 102.The transmit data signal component of analog input signal 102 isoperable to drive the LED when the LED transmit mode is active causingthe LED to emit light. The receive signal component of analog inputsignal 102 is affected by light received by the LED and the effect onthe receive signal component is representative of light being receivedby the LED.

FIG. 11B depicts data drive input circuit 96 that includes PWM module118 and mode enable module 122 and transmit/receive drive module 120integrated as one module. PWM module 118 includes a digital to analogconverter (DAC) 130, operational amplifier (op-amp) 132, and sawtoothgenerator 134. Mode enable module 122 and transmit/receive drive module120 includes multiplexor 141 and signal drive circuit 140. FIG. 11Bfurther includes a timing diagram of data drive input circuit 96'ssignals.

The DAC 130 of PWM module 118 is one of a sigma-delta DAC, a pulse widthmodulator DAC, a binary weighted DAC, a successive approximation DAC,and/or a thermometer-coded DAC. DAC 130 receives digital input signaldata_in and converts it to analog signal 136. Digital input signaldata_in is set based on a clock signal to ensure enough time fortransmit and receive components. Max transmit (TX) time shown in thetiming diagram represents the longest transmit time possible accordingto the data_in signal and thus the greatest light intensity transmitted.Shortening the transmit time lowers the light intensity.

Analog signal 136 varies based on data_in and is input to the positiveinput of op-amp 132. Sawtooth generator 134 generates a sawtooth signal138 in accordance with the clock signal 124 and is input to the negativeinput of op-amp 132.

Op-amp 132 generates PWM signal 128 by comparing analog signal 136 andthe sawtooth signal 138. The amplitude of the PWM signal 128 determinesthe transmit or receive mode and the pulse width determines the maxtransmit time. PWM signal 128 is input to the multiplexor of the modeenable module 122 and transmit/receive drive module 120. Based on thePWM signal 128, the multiplexor outputs either a transmit voltage (Vtx)or a receive voltage (Vrx). Vtx is equal to Vdd or less and Vrx is equalto Vss or more. Using less than Vdd for Vtx allows for more voltage tobe used in the receive mode. Allowing for more voltage in the receivemode improves light sensing capabilities.

The multiplexor 141 outputs either Vtx or Vrx to signal drive circuit140. Signal drive circuit 140 could be a bi-directional current orvoltage source and produces the analog output signal 102 based on theinput from the multiplexor 141. For example, when the multiplexorselects Vtx, the analog input signal 102 includes a transmit componentwith a transmit time depending on the light intensity that does notexceed the max transmit time. When the multiplexor selects Vrx theanalog input signal 102 includes the receive component.

FIG. 11C operates similarly to FIG. 11B except data drive input circuit96 of FIG. 11C does not include PWM module 118. Instead, input signaldata_in is input to both digital to analog converter (DAC) 130 and modeenable module 122 and transmit/receive drive module 120. Op-amp 132generates a transmit/receive (Tx/Rx) select signal 142 by comparinganalog signal 136 and the sawtooth signal 138. Mode enable module 122and transmit/receive drive module 120 processes data_in and uses Tx/Rxselect signal 142 to produce analog input signal 102 having transmit andreceive components.

FIG. 12 is a schematic block diagram of an embodiment of mode enablemodule 122 and transmit/receive drive module 120 that includes a data todivider module 154, reference oscillation module 148, phase locked loop(PLL) module 150, and oscillation conditioning circuit 156.

Data to divider module 154 includes transmit (TX) divider generator 144,receive (RX) divider generator 146, and a multiplexor module having oneor more multiplexors (e.g., shown here as two multiplexors 155 and 157).PLL module 150 includes one or more PLLs each having a range offrequencies selected based on input data. PLL module 150 is a closedloop system that locks the phase of its output to an input referencesignal. Oscillation conditioning circuit 156 includes a 180° phase shiftmodule 152 and signal drive circuit 140.

Reference oscillation module 148 generates a reference oscillationsignal for input into PLL module 150 and may be implemented in a varietyof ways. For example, the reference signal circuit 100 includes a DC(direct current) voltage generator, an AC voltage generator, and avoltage combining circuit. The DC voltage generator generates a DCvoltage at a first level and the AC voltage generator generates an ACvoltage at a second level, which is less than or equal to the firstlevel. The voltage combining circuit combines the DC and AC voltages toproduce the reference signal.

In an example of operation, data_in is input to TX divider generator 144and RX divider generator 146 of data to divider module 154. TX dividergenerator 144 generates a transmit divider value set (e.g., m_tx andn_tx) based on data_in. RX divider generator 146 generates a receivedivider value set (e.g., m_tx and n_tx) based on data_in. A firsttransmit value (e.g., m_tx) of the transmit divider value set is inputto multiplexor 155 of the multiplexor module and a second transmit value(e.g., n_tx) of the transmit divider value set is input to multiplexor157 of the multiplexor module.

A first receive value (e.g., m_rx) of the receive divider value set isinput to multiplexor 155 and a second receive value (e.g., n_rx) of thereceive divider value set is input to multiplexor 157 of the multiplexormodule. Multiplexors 155 and 157 are operable to output on transmitdivider value set or the receive divider value set based on the Tx/Rxselect signal 142 received to produce the divider value set (e.g., m andn).

The divider value set is input into PLL module 150 along with areference oscillation signal from reference oscillation module 148. PLLmodule 150 is operable to generate a fixed period, varying half cycleoscillation based on the reference oscillation and the divider valueset. PLL module 150 has a bandwidth that is greater than the data clockrate so the rate of the PLL module 150 can change in the desired timeframe for the transmit and receive periods.

PLL module 150 inputs the fixed period, varying half cycle oscillationto oscillation conditioning circuit 156. Oscillation conditioningcircuit 156 is operable to generate the analog input signal 102 based onthe fixed period, varying half cycle oscillation. In particular, 180°phase shift module 152 inverts the fixed period varying half cycleoscillation to produce an inverted oscillation cycle. Signal drivecircuit 140 produces the analog input signal 102 based on the invertedoscillation cycle. Note that, in an embodiment, the PLL module 150 has aloop response that is at a frequency that is greater than the frequency(i.e. 1 over the data rate) of the input data.

FIG. 13 is a schematic block diagram of an embodiment of a phase lockedloop (PLL) 180 that may be one or more PLLs of PLL module 150. PLLincludes input scalar (1/m) 158, phase &/or frequency detector 160,charge up/down pump 162, loop filter 164, voltage controlled oscillator(VCO) 166, and feedback divider (1/n) 168. PLL module 150 is a closedloop system that locks the phase of its output (e.g., output oscillation178) to an input reference signal (e.g., reference oscillation 170).

Input scalar (1/m) 158 multiplies reference oscillation 170 by 1/m(e.g., where m is input from the divider value set). Phase &/orfrequency detector 160 compares the scalar divided oscillation 170signal with the frequency and phase of the feedback signal to produce adigital pulse error signal that is proportional to the phase differencebetween the input and reference. Charge up/down pump 162 acts as abipolar switched current source and converts the digital pulse errorsignal of the phase &/or frequency detector 160 into analog errorcurrent signals suitable to control VCO 166.

Loop filter 164 integrates the charge up/down pump 162 output current toan equivalent VCO control voltage. VCO 166 is a low-swing oscillatorthat produces an output oscillation 178 frequency corresponding to theVCO control voltage. Feedback divider 168 divides output oscillation 178frequency by n (e.g., where n is input from the divider value set) andis fed for comparison to the reference oscillation 170. Frequencycontroller 172 sets a value for m 174 into input scalar (1/m) and avalue for n 176 into feedback divider (1/n) 168. As such, the outputoscillation frequency (PLL out) is equal to the reference oscillationfrequency (f_ref)×(n/m).

FIG. 14 is a schematic block diagram of signals of mode enable module122 and transmit/receive drive module 120 of FIG. 12. Data clock signaldata_clk has a fixed period long enough to account for a max transmittime and a receive time of the input signal (e.g., data_in). Data_in isa digital input signal with a fixed period. For example, for a firstclock cycle, data_in is equal to zero and for a second clock cycledata_in is equal to 255 (e.g., where 255 is a digital value for a maxtransmit pulse width or the highest intensity light output for the LED).Here, every clock cycle starts in a receive mode then transitions to atransmit mode if applicable to allow for transition delays.

Tx/Rx select signal is a high or low signal indicating a transmit mode(e.g., high) or a receive mode (e.g., low). For the first clock cycle,Tx/Rx select is in receive mode because the data_in signal is equal tozero. For the second clock cycle, the Tx/Rx select includes a receiveportion and the max transmit (TX) period. If data_in signal is somewherebetween 0 and 255, the transmit period will be shorter.

The oscillation reference signal (f_ref) is shown as a sinusoidal signalaligned with the data clock period. There may be one or more cycles ofoscillation per data clock cycle. PLL module 150 is operable to generatea fixed period, varying half cycle oscillation based on the referenceoscillation and the divider value set. The output of PLL module 150(e.g., PLL out) is equal to f_ref*(n/m) as discussed previously.

For the first clock cycle, receive mode is selected and data_in equals 0therefore, n is equal to the second receive divider value and m is thefirst second receive divider value. The PLL output is a half cycleoscillation that is shown as an entirely positive value when in thereceive mode. For the second clock cycle, data_in is 255 therefore,there is a receive mode selected first and a transmit mode selectedsecond having a max transmit period. During the receive portion, the PLLoutput is a half cycle oscillation shown as positive and during thetransmit mode the PLL output is a half cycle oscillation shown asnegative. The PLL output undergoes a 180° phase shift in the oscillationconditioning circuit and is output as analog input signal as shown.

FIG. 15 is a schematic block diagram of another embodiment of the modeenable module 122 and transmit/receive drive module 120 that includes areceive (RX) data to voltage 182, an RX voltage controlled oscillator184, a transmit (TX) data to voltage 186, a TX voltage controlledoscillator 188, 180° phase shift module 152, delay module 190,multiplexor 192, and signal drive circuit 140.

Data input signal (data_in) is input to RX data to voltage 182 and TXdata to voltage 186. RX data to voltage 182 produces an RX voltage basedon data_in and TX data to voltage 186 produces a TX voltage based ondata_in. RX voltage controlled oscillator (VCO) 184 produces a receivesinusoidal waveform based on the RX voltage. TX voltage controlledoscillator (VCO) 188 produces a transmit sinusoidal waveform based onthe TX voltage. Alternatively, an RX voltage to frequency converter anda TX voltage to frequency converter can be used in place of the RX andTX VCOs for better linearity over a wider range.

RX VCO 184 sends the receive sinusoidal waveform to 180° phase shiftmodule 152 to invert the waveform. 180° phase shift module 152 sends theinverted receive sinusoidal waveform to the delay module 190 where thedelay module 190 is controlled by the data_in signal.

Multiplexor 192 selects the transmit sinusoidal waveform or the invertedand delayed receive sinusoidal waveform based on a Tx/Rx select signal142 and outputs the selected signal to signal drive circuit 140. Signaldrive circuit 140 produces the analog input signal 102 based on theoutput of the multiplexor 192.

FIG. 16 is a schematic block diagram of signals of mode enable module122 and transmit/receive drive module 120 of FIG. 15. Data clock signaldata_clk has a fixed period long enough to account for a max transmittime and a receive time of the input signal (e.g., data_in). Data_in isa digital input signal with a fixed period. For example, for a firstclock cycle data_in, is equal to 255 (e.g., where 255 is a digital valuefor a max transmit pulse width or the highest intensity light output forthe LED) and for a second clock cycle data_in is equal to zero. Due tothe delay module 190 of FIG. 15, every clock cycle starts in a transmitmode then transitions to a receive mode if applicable.

Tx/Rx select signal is a high or low signal indicating a transmit mode(e.g., high) or a receive mode (e.g., low). For the first clock cycle,the Tx/Rx select indicates max transmit (TX) period and a receiveportion. If the data_in signal was somewhere between 0 and 255, thetransmit period will be shorter. For the second clock cycle, Tx/Rxselect is in receive mode because the data_in signal is equal to zero.

The output of TX VCO 188 (e.g., TX VCO out) is a transmit sinusoidalwaveform based on the TX voltage shown here as a positive waveform witha length equal to the max TX period. For all other times when the TXselect is not indicated, TX VCO out is zero.

The output of RX VCO 184 (e.g., RX VCO out) is a receive sinusoidalwaveform based on the RX voltage shown here as a positive waveform witha length equal to the time in the data clock cycle remaining after themax TX period. For the second clock cycle, data_in is equal to zero andRX select is indicated. As such, RX VCO out is shown as a positivewaveform with a length equal to the full data clock period.

180° phase shift module 152 inverts RX VCO out as shown as 1/RX VCO out.The delay module 190 delays the 1/RX VCO out signal such that it occursafter the max transmit period as shown at delayed 1/RX VCO out. Signaldrive circuit 140 outputs the TX VCO out waveform when Tx select isindicated and the delayed 1/RX VCO out waveform when RX mode isindicated. Thus, based on the Tx/Rx select signal indicated the analoginput signal 102 is shown as a combination of TX VCO out and delayed1/RX VCO.

FIG. 17 is a schematic block diagram of a light emitting diode (LED)touch display circuit 194 that includes two or more LEDs (e.g., a red(R) LED, a green (G) LED, and a blue (B) LED) separated by lightblocking spacers 196, processing module 52, and a plurality of LED touchsensors 50-1 through 50-3 corresponding to the LEDs. Lens 48 includesone or more light distribution properties, light concentrationproperties, filters, color masks, and embedded text elements and servesas a protective layer for the LEDs.

LED touch display circuit 194 operates similarly to the LED touchdisplay cell of FIG. 4 except for the addition of multiple LEDs, lightblocking spacers 196, and corresponding LED touch sensors 50-1 through50-3. With these additions, LED touch display circuit 194 operates eachLED in both a transmit mode to emit light and a receive mode to senselight. Therefore, in addition to sensing ambient light as previouslydiscussed, receive mode LEDs are operable to sense reflected light offof object 40 created by other LEDs in transmit mode.

In an example of operation, processing module 52 generates an inputsignal for each LED touch sensor 50_1 through 50_3 (e.g., R_data_in,G_data_in, and B_data_in). Each input signal is a repetitive signal thatincludes alternating transmit signal components and receive signalcomponents. The transmit signal component determines that the is intransmit mode and also includes a value for light intensity. The receivesignal component determines that the LED is in a receive mode.

When the transmit signal component is active, a corresponding LED touchsensor 50_1 through 50_3 forward biases its corresponding LED inaccordance with a light intensity value (e.g., a pulse width modulation(PWM) mode signal) of the transmit signal component such that thecorresponding LED emits light and illuminates lens 48. When the receivesignal component is active, the corresponding LED touch sensor 50_1through 50_3 reverse biases its LED such that the LED generates acurrent based on received light (e.g., ambient light 42, reflected light192, and/or a combination of ambient light 42 and reflected light 192)and generates a digital representation of the current. The correspondingLED touch sensor 50_1 through 50_3 produces a digital representation oflight intensity (e.g., data_Rx) based on the digital representation ofthe current.

As an example, the green and blue LEDs have different and longertransmit times (e.g., different PWM signals) than the red LED. When thered, green, and blue LEDs are in a receive mode, the LEDs sense ambientlight 42 around the LED touch display cell 38. Light blocking spacers196 block horizontal light detection between the LEDs and focus lightupwards towards incoming objects for maximum reflection. Interactions(e.g., a touch, hover, hover and gesture, etc.) can be detected based ona varying distance 44 of an object 40 (e.g., finger, pen, etc.) from theLEDs and how that affects the amount of ambient light 42 received by theLEDs.

The red LED continues to detect reflected light 192 from the green andblue LEDS when they switch to transmit mode. When the object approachesthe LEDs, the reflected light 192 increases. This combination of ambientlight 42 and reflected light 192 detection helps further identify object40 interactions (e.g., a touch, hover, hover and gesture, etc.)especially when ambient light levels are low. The processing module 52interprets the digital representation of the light intensity todetermine an output response 56 (e.g., touch, hover, etc.).

While green, red, and blue LEDs are shown here, other colors and/ortypes of LEDs may be chosen. For example, an infra-red LED may be usedin the receive mode to detect light while visible spectrum LEDs are usedfor both receive and transmit modes.

In another embodiment, a touch, hover, and/or gesture is determinedbased on blurred image processing. In a non-lensed embodiment, light isnot focused sharply on the LEDs. As such, a 2D image from the LEDs isfuzzy (low frequency) and has indistinct edges. As an object approachesthe LEDs, the blur lessens and the image becomes sharper. When contactis made by an object on the LEDs, there is a sharper transition betweenthe blocked LEDs and unblocked LEDs around the perimeter of the object,which can generally be recognized because there is a cluster of LEDsthat is blocked. A variety of algorithms can be used to detect theobject and properties thereof (i.e., looking for the least blur and/orthe maximum sharpness).

In an example, a contrast method is used in the time domain. The imagecreated by the LEDs in receive and/or transmit mode is analyzed forhighest contrast. A blurred image has low contrast. As the image becomessharper (e.g., as an object approaches the LEDS), the contrastincreases. Maximum contrast occurs when a physical touch is made(contrast is high around the sharper boundaries).

In another example, a high frequency method is used in the frequencydomain. In this method, Fourier analyses is used to determine frequencycomponents of the blurred image produced by the LEDs. When there is noreflected light (e.g., no object nearby), the frequency spectrum of theblurred image includes low frequency components with very few, if any,high frequency components. As an object comes closer to the LEDS, edgesbecome sharper which means there are an increase in high and/or higherfrequency components (more frequency components in general). In aspecific example, the high contrast edges are like a rising pulse whichcontains many higher frequency components. The maximum number of highfrequency components occur at the point of contact.

FIG. 18 is a schematic block diagram of an example of transmit andreceive select signals of light emitting diodes (LEDs) of FIG. 17.Transmit-receive (Tx-Rx) signal contains a transmit mode component and areceive mode component (e.g., a high signal indicates a transmit mode,and a low signal indicates a receive mode). During one clock cycle, LEDsare in transmit mode no longer than the max transmit mode then switch toreceive mode at different times. For example, a max transmit period isequal to 255 (e.g., where 255 is a digital value for a max transmitpulse width or the highest intensity light output for the LED).

The digital value of 255 comes from hypertext markup language (HTML)color codes where various colors are created (e.g., transmitted) basedon red, green, and blue light intensity levels. For example, white lightis created when red, green, and blue light are equal to 255 maxintensity. As another example, for turquoise light, red is equal to 64,green is 224, and blue is 228. Over 16 million color combinations exist.

In this example, the blue LED has a max transmit period equal to 255while green and red have shorter transmit periods. When the red LED'stransmit period is over, red senses blue and green reflected light aswell as ambient light for a period of time while the green and blue LEDare still in transmit mode. When the green LED's transmit period isover, the red and green LED sense blue reflected light as well asambient light while the blue LED is still in transmit mode. When theblue LED's transmit period is over, all three LEDs are in receive modeand sense ambient light as discussed with previous Figures.

FIGS. 19A-19B depict graphs of light 198 versus object distance 200 fromthe LED touch display circuit. As shown in FIG. 19A, the lightmeasurement includes a reflected light component 192 and an ambientlight component 42. The max ambient light level occurs when objects arefurther away from the LED touch display circuit (e.g., at a greaterdistance 200) such that ambient light is not obstructed. Converselyreflected light levels increase when objects are closer to the LED touchdisplay circuit.

When all LEDs are in the receive mode the ambient light 42 curve is usedto detect interactions. For example, an ambient light hover threshold202 is defined as being between an ambient light level associated with adistance d2 from the LED touch display circuit and an ambient lightlevel associated with a distance d1 from the LED touch display circuit.The level of ambient light associated with a distance d2 is at a higherintensity than the ambient light level associated with a distance d1 anddistance d2 is further from the LED touch cell surface than d1.

An ambient touch threshold 204 is defined as being between a level ofambient light associated with a distance d1 and zero ambient light at adistance zero. The processing module processes the digitalrepresentation of the light intensity to determine an ambient lightpattern and is able to determine a hover indication when the ambientlight pattern deviates from the maximum ambient light level to theambient light hover threshold 202. The processing module can thenprocess the hover indication to generate the response output. Theprocessing module processes the digital representation of the lightintensity to determine an ambient light pattern and is able to determinea touch indication when the ambient light pattern deviates from the maxambient light or the ambient light hover threshold 202 to the ambienttouch threshold 204. The processing module can then process the touchindication to generate the response output.

As shown in FIG. 19B, when at least some LEDs are in transmit mode, acombination of the reflected light curve 192 and the ambient light curveis used to detect interactions. The combined light curve 206 is anapproximation of combined light when maximum reflected light is muchgreater than maximum ambient light (e.g., the ambient light is moderateto low).

For example, a combination light hover threshold 210 is defined as beingbetween a combined light level associated with a distance d2 from theLED touch display circuit and a combined light level associated with adistance d1 from the LED touch display circuit. The level of combinedlight associated with a distance d2 is at a lower intensity than thecombined light level associated with a distance d1 and distance d2 isfurther from the LED touch display surface than d1.

A combination touch threshold 208 is defined as being between a level ofcombined light associated with distance d1 and a maximum light at adistance zero. The processing module processes the digitalrepresentation of the light intensity to determine a light pattern andbased on whether at least some LEDs are in transmit mode is able todetermine a hover indication when the light pattern indicates thecombined light hover threshold 210.

The processing module can then process the hover indication to generatethe response output. The processing module is able to determine a touchindication when the light pattern indicated the combination touchthreshold 208. The processing module can then process the touchindication to generate the response output.

FIG. 20 is a logic diagram of an example of a method of light basedtouch detection by a light emitting diode (LED) touch display circuit.For example, LED touch display circuit includes a first LED coupled to afirst LED touch sensor and a second LED coupled to a second LED touchsensor where the first LED and a second LED are separated by lightblocking spacers. The LED touch display circuit can include more thantwo LEDs (e.g., a red LED, a green LED, and a blue LED).

The method begins with step 212 where a processing module of the LEDtouch display circuit generates a data input signal in accordance with asample clock rate. For example, the sample clock rate is 1/50microseconds or 20 KHz. The method continues with step 214 where thefirst and second LED touch sensor of the LED touch display circuitconvert the data input signal into first and second LED signals (e.g.,transmit-receive signals). The first LED signal includes a firsttransmit signal component and a first receive signal component and thesecond LED signal includes a second transmit signal component and asecond receive signal component

When in an ambient light sense mode, the method continues with steps84-94 of FIG. 7 for each of the first and second LED. For example, thefirst LED touch sensor receives a first current from the first LED andthe second LED touch sensor receives a second current from the secondLED. The first LED touch sensor generates first digital representationsof the first current from the first LED and the second LED touch sensorgenerates second digital representations of the second current from thesecond LED.

The first LED touch sensor generates first digital representations offirst light intensity from the first digital representations of currentand the second LED touch sensor generates second digital representationsof second light intensity from the second digital representations of thesecond current. The first and second LED touch sensors send the firstdigital representations of first light intensity and the second digitalrepresentations of second light intensity to the processing module. Theprocessing module processes the first and second digital representationsof first and second light intensity to determine an ambient lightpattern and interprets the ambient light pattern to determine aninteraction (e.g., hover, touch, gesture, etc.).

When in a combined light sense mode (e.g., ambient light and reflectedlight are sensed), the method continues with step 218 where during atleast a portion of the first receive signal component and at least aportion of the second transmit signal component (e.g., the secondtransmit period is still going while the first receive componentbegins), the first LED touch sensor receives the first current from thefirst LED.

The method continues with step 220 where the first LED touch sensorgenerates first digital representations of the first current from thefirst LED. The method continues with step 222 where the first LED touchsensor generates first digital representations of first light intensityfrom the first digital representations of the first current.

The method continues with step 224 where the first LED touch sensorsends the first digital representations of the first light intensity tothe processing module. The method continues with step 226 where theprocessing module processes the first digital representations of thefirst light intensity to determine a combined light pattern. Thecombined light pattern is representative of ambient light and reflectedlight emitted from the second LED.

The method continues with step 228 where the processing moduleinterprets the combined light pattern to determine an interaction (e.g.,touch, hover, gesture, etc.). For example, a combination light hoverthreshold is defined as being between a combined light level associatedwith a distance d2 from the LED touch display circuit and a combinedlight level associated with a distance d1 from the LED touch displaycircuit. The level of combined light associated with a distance d2 is ata lower intensity than the combined light level associated with adistance d1 and distance d2 is further from the LED touch displaysurface than d1. The combined light pattern can be processed todetermine a hover interaction based on the combination hover threshold.

A combination touch threshold is defined as being between a level ofcombined light associated with distance d1 and a maximum light at adistance zero from the LED touch display surface. The combined lightpattern can be processed to determine a touch interaction based on thecombination touch threshold.

The method continues with step 230 where the processing module processesthe interaction to generate a response output. For example, a tap,swipe, length of touch/hover, and/or or other such gesture may beidentified and processed to perform various actions (e.g., power on/off,volume change, lighting change, etc.). A hover interaction may bedetermined and then the processing module waits for further gestureinformation.

As may be used herein, the terms “substantially” and “approximately”provide an industry-accepted tolerance for its corresponding term and/orrelativity between items. For some industries, an industry-acceptedtolerance is less than one percent and, for other industries, theindustry-accepted tolerance is 10 percent or more. Other examples ofindustry-accepted tolerance range from less than one percent to fiftypercent. Industry-accepted tolerances correspond to, but are not limitedto, component values, integrated circuit process variations, temperaturevariations, rise and fall times, thermal noise, dimensions, signalingerrors, dropped packets, temperatures, pressures, material compositions,and/or performance metrics. Within an industry, tolerance variances ofaccepted tolerances may be more or less than a percentage level (e.g.,dimension tolerance of less than +/−1%). Some relativity between itemsmay range from a difference of less than a percentage level to a fewpercent. Other relativity between items may range from a difference of afew percent to magnitude of differences.

As may also be used herein, the term(s) “configured to”, “operablycoupled to”, “coupled to”, and/or “coupling” includes direct couplingbetween items and/or indirect coupling between items via an interveningitem (e.g., an item includes, but is not limited to, a component, anelement, a circuit, and/or a module) where, for an example of indirectcoupling, the intervening item does not modify the information of asignal but may adjust its current level, voltage level, and/or powerlevel. As may further be used herein, inferred coupling (i.e., where oneelement is coupled to another element by inference) includes direct andindirect coupling between two items in the same manner as “coupled to”.

As may even further be used herein, the term “configured to”, “operableto”, “coupled to”, or “operably coupled to” indicates that an itemincludes one or more of power connections, input(s), output(s), etc., toperform, when activated, one or more its corresponding functions and mayfurther include inferred coupling to one or more other items. As maystill further be used herein, the term “associated with”, includesdirect and/or indirect coupling of separate items and/or one item beingembedded within another item.

As may be used herein, the term “compares favorably”, indicates that acomparison between two or more items, signals, etc., provides a desiredrelationship. For example, when the desired relationship is that signal1 has a greater magnitude than signal 2, a favorable comparison may beachieved when the magnitude of signal 1 is greater than that of signal 2or when the magnitude of signal 2 is less than that of signal 1. As maybe used herein, the term “compares unfavorably”, indicates that acomparison between two or more items, signals, etc., fails to providethe desired relationship.

As may be used herein, one or more claims may include, in a specificform of this generic form, the phrase “at least one of a, b, and c” orof this generic form “at least one of a, b, or c”, with more or lesselements than “a”, “b”, and “c”. In either phrasing, the phrases are tobe interpreted identically. In particular, “at least one of a, b, and c”is equivalent to “at least one of a, b, or c” and shall mean a, b,and/or c. As an example, it means: “a” only, “b” only, “c” only, “a” and“b”, “a” and “c”, “b” and “c”, and/or “a”, “b”, and “c”.

As may also be used herein, the terms “processing module”, “processingcircuit”, “processor”, “processing circuitry”, and/or “processing unit”may be a single processing device or a plurality of processing devices.Such a processing device may be a microprocessor, micro-controller,digital signal processor, microcomputer, central processing unit, fieldprogrammable gate array, programmable logic device, state machine, logiccircuitry, analog circuitry, digital circuitry, and/or any device thatmanipulates signals (analog and/or digital) based on hard coding of thecircuitry and/or operational instructions. The processing module,module, processing circuit, processing circuitry, and/or processing unitmay be, or further include, memory and/or an integrated memory element,which may be a single memory device, a plurality of memory devices,and/or embedded circuitry of another processing module, module,processing circuit, processing circuitry, and/or processing unit. Such amemory device may be a read-only memory, random access memory, volatilememory, non-volatile memory, static memory, dynamic memory, flashmemory, cache memory, and/or any device that stores digital information.Note that if the processing module, module, processing circuit,processing circuitry, and/or processing unit includes more than oneprocessing device, the processing devices may be centrally located(e.g., directly coupled together via a wired and/or wireless busstructure) or may be distributedly located (e.g., cloud computing viaindirect coupling via a local area network and/or a wide area network).Further note that if the processing module, module, processing circuit,processing circuitry and/or processing unit implements one or more ofits functions via a state machine, analog circuitry, digital circuitry,and/or logic circuitry, the memory and/or memory element storing thecorresponding operational instructions may be embedded within, orexternal to, the circuitry comprising the state machine, analogcircuitry, digital circuitry, and/or logic circuitry. Still further notethat, the memory element may store, and the processing module, module,processing circuit, processing circuitry and/or processing unitexecutes, hard coded and/or operational instructions corresponding to atleast some of the steps and/or functions illustrated in one or more ofthe Figures. Such a memory device or memory element can be included inan article of manufacture.

One or more embodiments have been described above with the aid of methodsteps illustrating the performance of specified functions andrelationships thereof. The boundaries and sequence of these functionalbuilding blocks and method steps have been arbitrarily defined hereinfor convenience of description. Alternate boundaries and sequences canbe defined so long as the specified functions and relationships areappropriately performed. Any such alternate boundaries or sequences arethus within the scope and spirit of the claims. Further, the boundariesof these functional building blocks have been arbitrarily defined forconvenience of description. Alternate boundaries could be defined aslong as the certain significant functions are appropriately performed.Similarly, flow diagram blocks may also have been arbitrarily definedherein to illustrate certain significant functionality.

To the extent used, the flow diagram block boundaries and sequence couldhave been defined otherwise and still perform the certain significantfunctionality. Such alternate definitions of both functional buildingblocks and flow diagram blocks and sequences are thus within the scopeand spirit of the claims. One of average skill in the art will alsorecognize that the functional building blocks, and other illustrativeblocks, modules and components herein, can be implemented as illustratedor by discrete components, application specific integrated circuits,processors executing appropriate software and the like or anycombination thereof.

In addition, a flow diagram may include a “start” and/or “continue”indication. The “start” and “continue” indications reflect that thesteps presented can optionally be incorporated in or otherwise used inconjunction with one or more other routines. In addition, a flow diagrammay include an “end” and/or “continue” indication. The “end” and/or“continue” indications reflect that the steps presented can end asdescribed and shown or optionally be incorporated in or otherwise usedin conjunction with one or more other routines. In this context, “start”indicates the beginning of the first step presented and may be precededby other activities not specifically shown. Further, the “continue”indication reflects that the steps presented may be performed multipletimes and/or may be succeeded by other activities not specificallyshown. Further, while a flow diagram indicates a particular ordering ofsteps, other orderings are likewise possible provided that theprinciples of causality are maintained.

The one or more embodiments are used herein to illustrate one or moreaspects, one or more features, one or more concepts, and/or one or moreexamples. A physical embodiment of an apparatus, an article ofmanufacture, a machine, and/or of a process may include one or more ofthe aspects, features, concepts, examples, etc. described with referenceto one or more of the embodiments discussed herein. Further, from figureto figure, the embodiments may incorporate the same or similarly namedfunctions, steps, modules, etc. that may use the same or differentreference numbers and, as such, the functions, steps, modules, etc. maybe the same or similar functions, steps, modules, etc. or differentones.

While the transistors in the above described figure(s) is/are shown asfield effect transistors (FETs), as one of ordinary skill in the artwill appreciate, the transistors may be implemented using any type oftransistor structure including, but not limited to, bipolar, metal oxidesemiconductor field effect transistors (MOSFET), N-well transistors,P-well transistors, enhancement mode, depletion mode, and zero voltagethreshold (VT) transistors.

Unless specifically stated to the contra, signals to, from, and/orbetween elements in a figure of any of the figures presented herein maybe analog or digital, continuous time or discrete time, and single-endedor differential. For instance, if a signal path is shown as asingle-ended path, it also represents a differential signal path.Similarly, if a signal path is shown as a differential path, it alsorepresents a single-ended signal path. While one or more particulararchitectures are described herein, other architectures can likewise beimplemented that use one or more data buses not expressly shown, directconnectivity between elements, and/or indirect coupling between otherelements as recognized by one of average skill in the art.

The term “module” is used in the description of one or more of theembodiments. A module implements one or more functions via a device suchas a processor or other processing device or other hardware that mayinclude or operate in association with a memory that stores operationalinstructions. A module may operate independently and/or in conjunctionwith software and/or firmware. As also used herein, a module may containone or more sub-modules, each of which may be one or more modules.

As may further be used herein, a computer readable memory includes oneor more memory elements. A memory element may be a separate memorydevice, multiple memory devices, or a set of memory locations within amemory device. Such a memory device may be a read-only memory, randomaccess memory, volatile memory, non-volatile memory, static memory,dynamic memory, flash memory, cache memory, and/or any device thatstores digital information. The memory device may be in a form asolid-state memory, a hard drive memory, cloud memory, thumb drive,server memory, computing device memory, and/or other physical medium forstoring digital information.

While particular combinations of various functions and features of theone or more embodiments have been expressly described herein, othercombinations of these features and functions are likewise possible. Thepresent disclosure is not limited by the particular examples disclosedherein and expressly incorporates these other combinations.

What is claimed is:
 1. A touch display apparatus comprising: a pluralityof light emitting diodes (LEDs), wherein a light emitting diode (LED) ofthe plurality of LEDs is configured to emit light having a wavelengththat is different than another wavelength of another LED of theplurality of LEDs; a plurality of light blocking spacers, wherein alight blocking spacer of the plurality of light blocking spacers isimplemented adjacent to the LED of the plurality of LEDs and isconfigured to block light horizontal light detection from another LED ofthe plurality of LEDs; a plurality of LED touch sensors, wherein an LEDtouch sensor of the plurality of LED touch sensors is operably coupledto the LED of the plurality of LEDs and includes: a data drive inputcircuit, wherein when enabled, the data drive input circuit isconfigured to generate a transmit-receive signal that is based on adigital input, wherein the transmit-receive signal is configured tofacilitate operation of the LED touch sensor in accordance with atransmit mode and a receive mode based on different respectivecomponents of the transmit-receive signal; a drive-sense circuit (DSC)operably coupled to the data drive input circuit, wherein when enabled,the DSC is configured to operate in accordance with the transmit modeand the receive mode based on the different respective components of thetransmit-receive signal including to: forward bias the LED to facilitatethe LED emitting light in accordance with a light intensity value basedon the transmit mode; and reverse bias the LED to facilitate the LEDgenerating a current based on the LED receiving light based on thereceive mode and to generate a digital representation of the current;and a data output circuit operably coupled to DSC, wherein when enabled,the data output circuit is configured to generate a digitalrepresentation of light intensity based on the digital representation ofthe current that is generated by the DSC.
 2. The touch display apparatusof claim 1, wherein the plurality of LEDs comprises an LED configured toemit red light (red LED), one or more LEDs configured to emit greenlight (green LED) and an LED configured to emit blue light (blue LED).3. The touch display apparatus of claim 2, wherein the DSC is configuredto forward bias the red LED during a time period T, when either of thegreen LED or the blue LED is reverse biased.
 4. The touch displayapparatus of claim 1, wherein the plurality of LEDs comprises an LEDconfigured to emit at least one of infrared light (IR LED), ultravioletlight (UV LED) and visible light (visible light LED).
 5. The touchdisplay apparatus of claim 4, wherein the DSC is configured to forwardbias the IR LED while either of the UV LED or the visible light LED isreverse biased.
 6. The touch display apparatus of claim 1, wherein theplurality of LEDs is configured in an array having a respective topsurface and a respective bottom surface, wherein the plurality of LEDsare configured to emit light from the top surface, the touch displayapparatus further comprising: one or more lenses proximal to the topsurface of the plurality of LEDs, wherein each of the one or more lensesis adapted to at least one of: distribute light received at an LED ofthe plurality of LEDS; concentrate light received at an LED of theplurality of LEDS; filter light received at an LED of the plurality ofLEDS; mask light outside one or more predetermined wavelengths receivedat an LED of the plurality of LEDS; mask light outside one or morepredetermined wavelengths emitted by an LED of the plurality of LEDS;embed one or more text elements masks; and protect the top surface ofthe plurality of LEDs.
 7. The touch display apparatus of claim 1,wherein the LED is forward biased based using a pulse width modulated(PWM) signal, wherein a duty cycle for the PWM signal is modified torepresent a predetermined light intensity value during the transmitmode, wherein the duty cycle is a fraction of time in a time windowduring which a current is applied to the LED.
 8. The touch displayapparatus of claim 7, wherein the plurality of LEDs comprises an LEDconfigured to emit red light (red LED), one or more LEDs configured toemit green light (green LED) and an LED configured to emit blue light(blue LED, wherein the red LED is forward biased using a duty cycle thatis different than either of the green LED or the blue LED.
 9. The touchdisplay apparatus of claim 1, wherein a digital representation of lightintensity is output for each LED of the plurality of LEDs to produce animage, wherein a ratio of light intensity between two or more LEDs ofthe plurality of LEDs is used to determine one or more light intensitytransitions between LEDs of the plurality of LEDs.
 10. The touch displayapparatus of claim 9, wherein the ratio of light intensity between thetwo or more LEDs is determined over a time period I, wherein the ratiois used to determine a highest contrast between light intensitytransitions during time period I.
 11. The touch display apparatus ofclaim 1, wherein the light blocking spacer is further configured tofocus light upwards towards an object.
 12. The touch display apparatusof claim 1, wherein a digital representation of light intensity isoutput for each LED of the plurality of LEDs to produce an image,wherein a frequency component is determined one or more light intensitytransitions between LEDs of the plurality of LEDs, wherein a ratio oflow frequency components to high frequency components for two or moreLEDs is used to determine one or more light intensity transitionsbetween one or more LEDs of the plurality of LEDs.
 13. A touch displayapparatus comprising: a plurality of groups of light emitting diodes(LEDs), wherein a light emitting diode (LED) of a group of LEDs isconfigured to emit light having a wavelength that is different thananother wavelength of another LED of the group of LEDs; a plurality oflight blocking spacers, wherein a light blocking spacer of the pluralityof light blocking spacers is implemented adjacent to the LED of thegroup of LEDs and is configured to block light horizontal lightdetection from another LED of the group of LEDs; a plurality of LEDtouch sensors, wherein an LED touch sensor of the plurality of LED touchsensors is operably coupled to the LED of the plurality of LEDs andincludes: a data drive input circuit, wherein when enabled, the datadrive input circuit is configured to generate a transmit-receive signalthat is based on a digital input, wherein the transmit-receive signal isconfigured to facilitate operation of the LED touch sensor in accordancewith a transmit mode and a receive mode based on different respectivecomponents of the transmit-receive signal; a drive-sense circuit (DSC)operably coupled to the data drive input circuit, wherein when enabled,the DSC is configured to operate in accordance with the transmit modeand the receive mode based on the different respective components of thetransmit-receive signal including to: forward bias the LED to facilitatethe LED emitting light in accordance with a light intensity value basedon the transmit mode; and reverse bias the LED to facilitate the LEDgenerating a current based on the LED receiving light based on thereceive mode and to generate a digital representation of the current;and a data output circuit operably coupled to DSC, wherein when enabled,the data output circuit is configured to generate a digitalrepresentation of light intensity based on the digital representation ofthe current that is generated by the DSC.
 14. The touch displayapparatus of claim 13, wherein the group of LEDs comprises an LEDconfigured to emit red light (red LED), one or more LEDs configured toemit green light (green LED) and an LED configured to emit blue light(blue LED).
 15. The touch display apparatus of claim 13, wherein thegroup of LEDs comprises an LED configured to emit at least one ofinfrared light (IR LED), ultraviolet light (UV LED) and one or morevisible light LEDs (visible light LED).
 16. The touch display apparatusof claim 13, wherein the plurality of groups of LEDs is configured in anarray having a respective top surface and a respective bottom surface,wherein the plurality of LEDs are configured to emit light from the topsurface, the touch display apparatus further comprising: one or morelenses proximal to the top surface of the plurality of LEDs, whereineach of the one or more lenses is adapted to at least one of: distributelight received at an LED of the plurality of groups of LEDS; concentratelight received at an LED of the plurality of groups of LEDS; filterlight received at an LED of the plurality of groups of LEDS; mask lightoutside one or more predetermined wavelengths received at an LED of theplurality of groups of LEDS; mask light outside one or morepredetermined wavelengths emitted by an LED of the plurality of groupsof LEDS; embed one or more text element masks; and protect the topsurface of the plurality of groups of LEDs.
 17. The touch displayapparatus of claim 13, wherein a digital representation of lightintensity is output for each LED of the plurality of groups of LEDs toproduce an image, wherein a ratio of light intensity between two or moreLEDs of the group of LEDs is used to determine one or more lightintensity transitions between LEDs of the plurality of groups of LEDs.18. The touch display apparatus of claim 17, wherein the ratio of lightintensity between two or more LEDs is determined over a time period I,wherein the ratio of light intensity between the two or more LEDs overthe time period I is used to determine a highest contrast for one ormore light intensity transitions during time period I.
 19. The touchdisplay apparatus of claim 13, wherein a digital representation of lightintensity is output for each LED of the plurality of groups of LEDs toproduce an image, wherein a frequency component is determined for atleast a portion of the LEDs of the plurality of groups of LEDs over atime period P, wherein a ratio of low frequency components to highfrequency components for two or more LEDs of the at least a portion ofthe LEDs of the plurality of groups of LEDs is used to determine one ormore light intensity transitions between one or more LEDs of theplurality of LEDs.
 20. The touch display apparatus of claim 13, whereinthe light blocking spacer is further configured to focus light upwardstowards an object.